ACRYLIC SHEET
Forming
Manual
TABLE OF CONTENTS
3
Introduction
22
4
Methods of Heating
Forming Methods
22 Preparation of Sheets for Forming
22 Two-Dimensional Forming
4 Air Oven Heating
22 Cold Forming
6 Air-Operated Release for Oven Clamps
and Clamping Station
22 Strip Heat Bending
23 Drape Forming
6 Infrared Radiant Heating
23 Three-Dimensional Forming
8 Strip Heating
24 Free Forming
9 Other Methods of Heating
26 Estimating Pressure Required for
Free Blowing or Vacuum Forming
9 Special Considerations for Forming
Plexiglas® MC acrylic sheet
11
26 Vacuum Snapback Forming
26 Vacuum Drawing or Blowing into a Form
Forming Temperatures and Cycles
28 Manual Stretch Forming
12 Time Available for Forming
29 Slip Forming
12 Slow Cooling
29 Plug and Ring Forming
12 Reforming
29 Vacuum Assist Plug and Ring Forming
13
30 Blowback Forming
Forming Equipment
13 Presses
31 Billow Forming
13 Clamp Rings and Clamps
32 Ridge Forming
17 Vacuum Forming Equipment
33 Male and Female Forming
33 Surface Embossing
19
®
Forms for Plexiglas Acrylic Sheet
19 Contour Tolerances and Effects of Forming
19 Shrinkage Allowances
19 Materials for Forms
19 Wood Forms
19 Resin Impregnate Forms
20 Metal Forms
20 Cast Forms
20 Gypsum Forms
21 Resin Forms
21 Surfaces of Forms
21 Grease-Covered Forms
2
34
General Health and Safety Precautions
INTRODUCTION
One of the most useful properties of Plexiglas® acrylic
sheet is its thermoformability. Being thermoplastic, it
becomes soft and pliable when heated and can then be
formed to almost any desired shape. As the material
cools, it stiffens and retains the shape to which it has
been formed.
The size, shape and optical requirements of the formed
part generally govern the choice of forming method to
be used. Regardless of the method used, the following
principles must be observed for best results.
1. The whole sheet should be heated uniformly to the
proper forming temperature (Exception: see Strip
Heating, page 8).
2. The sheet should be completely formed before it
cools below the minimum forming temperature.
3. The part should be cooled slowly and uniformly
while being held in its formed shape and removed
from the mold while still warm.
Most of the information in this Manual is applicable for
all grades of Plexiglas® acrylic sheet, except for some
applications related to Plexiglas® MC acrylic sheet. Any
exceptions are noted in the appropriate sections.
3
METHODS OF HEATING
Forced-circulation air oven heating provides the best protection
against overheating the sheet, develops the least amount of
temperature gradient throughout the thickness of the sheet,
results in longer heating cycles, and is highly recommended
when heating sheet 0.354 inches and thicker. Infrared heating,
which is generally associated with automatic or semi-automatic
operations, results in shorter heating cycles, and should be
used with sheet thicknesses of less than 0.354 inches. Infrared
heating can result in uneven heating, if the heating elements
begin to lose their heating ability over time. Infrared heating can
degrade the sheet if the heating cycle is exceeded. Strip-heat
bending utilizes infrared elements and may degrade the sheet if
heating cycles are exceeded. It is limited to two-dimensional
forming but is viable for bending sheet thicknesses of up to
about two inches. A typical forced-circulation air oven is shown
in Figure 1. For heating equipment suppliers and sources of
other accessories, call the Altuglas International Polymer
Technology Center at 800-217-3258.
Air Oven Heating
Generally, the whole piece of Plexiglas® acrylic sheet is heated
before forming in a hot air oven with forced circulation (Figure 1). The
basic elements of such an oven are an insulated chamber of suffi­
cient size, which is provided with a means to force-circulate the
air, and a means of heating, which may be either gas or electricity.
Gas ovens should be designed with heat exchangers so that
the flue gases are not used as the actual heating medium. Baffles
should be used to direct the heated air from the heating elements
to the Plexiglas® acrylic sheet. The sheet should be protected from
radiation to eliminate hot spots.
When an electric oven is to be used, the heating elements
should be designed to be easily removed, so that they can be
serviced and replaced with ease. It is also desirable to use a
switch capable of converting the wiring from series to parallel
rather than a simple on-off switch. A series/parallel switch reduces
power to the elements when actuated by the thermoregulator
but does not switch the power off. This mode of operation provides
a more uniform oven temperature.
4
To prevent thermal damage to the sheet, maximum oven air
temperatures should be carefully controlled. Automatic
temperature regulators must be provided. Temperature recording
devices are desirable, although not absolutely essential. The
accuracy of temperature controls should be checked occasionally
by means of a maximum reading thermometer hung in the oven
near the sheets.
It is extremely important to wire the heater elements and air
circulating blowers into the same circuit. If these units are on
separate circuits a potential fire hazard exists. In such a case, it
would be possible for the heater to be operating when the
blowers were not. Without air circulating, the elements could
overheat and cause a fire.
Forced circulation of air and suitable baffles are necessary to
distribute the heat evenly throughout the oven so that each sheet
will be heated uniformly over its entire surface and so that all
sheets will be heated to the same temperature. It is very important
that air be circulated across the surface of the sheet at a velocity
from 150 to 250 cubic feet per minute. For efficient heating,
ovens should have two narrow doors to prevent excessive heat
loss while loading and unloading the sheets. This will allow for the
introduction of large formed parts for reheating and flattening if
reforming is necessary.
Small sheets may be supported in trays lined with soft cloth
or woven fiberglass cloth or fiberglass coated with sintered
Teflon® to protect the surface of the plastic from scratching.
Large Plexiglas® acrylic sheets should be hung vertically from
racks. Overhead racks for hanging sheets may be equipped with
tracks and trolleys leading to forming equipment to facilitate
handling of the sheet. Note the Special Considerations section
for Plexiglas® MC acrylic sheet on page 9.
FIGURE 1
Typical Forced-Circulation Air Oven
Series P-1000 Unistrut
Trolley Rails
Sheet Metal Corner Closure Angles
View of Oven for Heating 100" x 120" Plexiglas®
Acrylic Sheet Panels
V-Belts 1:2
Reduction
Series P-1001
Unistrut Fan &
Motor Chan. Rails
Ball Bearing
Pillow Blocks
Doors to Open Full Without
Center Column to Permit
Platening of Formed Parts
Locate Fan Bearings,
Belts & Motors Outside
of Oven Away from Heat.
Minimum 1" Diam.
(drill rod) Shaft
or 2" Diam.
Chrome
Steel Shaft.
Continuous
Sheet Metal
Baffles-Adjust
for Best
Air Flow
Thermo. Bulb
Trolley Racks
for Holding Plexiglas®
Acrylic Sheet
H.P.
A
Motor Will
Drive Two
24" Fans at
800 R.P.M.
Gas Heating
Manifolds
Elec. Heating
Elements
9"→ 12"→
→
→
13"→
→
H.P.
3⁄
4
9"→
→
Baffles
Section Through Oven
2" Marinite
Panel
Insulation
1⁄
4"
Cast Bronze or Steel Four-Blade
24" Diam. 800 R.P.M. —Each Fan
to Move 2,000 C.F.M.
Electric Heating Elements
Flat Plywood
(scuff protection)
This Partition to
be Sheathed with
Sheet Metal &
Insulated as
Shown
Insulation on
Sheathing
Service Access Panel
Partially Open
→
6" Min.
Series P-1000
Unistrut for
Trolley Rails
1'2"’
79" Dimen. of 67"x79" Plexiglas®
100" Dimen. of 100"x120" Plexiglas®
3⁄
4
Cable
Supports
Series P-2000 Unistrut
for Structural Framing
Return Air
Openings
Interior View Fan Side
5
Air-Operated Release for Oven Clamps and Clamping Station
Infrared Radiant Heating
Figure 3 depicts a clamping station with an air-operated
release mechanism for hanging Plexiglas® acrylic sheets in heating
ovens. This device can reduce appreciably the labor required for
clamping and unclamping sheets preparatory to forming. It can
also shorten the time required to transport the heated sheet
from the oven to the forming equipment, thus minimizing the
possibility of cold forming.
The principal advantage of radiant heating over convection oven
heating is speed. Radiant heating time cycles for 0.118-inch thick
Plexiglas® acrylic sheet heated from one side may vary from one
to three minutes, depending on the type of heater and the distance
from the heating surface to the Plexiglas® acrylic sheet compared
with about 10 to 12 minutes for air-oven heating. Ambient oven
temperature also affects the heating cycle.
The design of the unit permits the operator to open all the
clamps at once by simply opening a valve on the air line. After
the sheet has been placed in the clamps, they are closed by
shutting the air valve and venting the air pressure in the cylinders.
The air pressure and vent line can be operated by a foot control
so that the fabricator’s hands are free to grip the sheet.
Temperature uniformity varies with heater model. Heaters that
produce uniform surface temperatures can be located closer to
the Plexiglas® acrylic sheet for better energy efficiency.
In a permanent installation, the clamping station can be welded
to the trolley rail. In temporary operations, the station can be
moved to various locations and bolted to any section of trolley
rail in the shop.
An automatic clamping unit of the type mentioned above is
essential for high-volume forming, however, smaller operations
can function successfully with less elaborate systems constructed
from standard spring paper clips as shown in Figure 2. Spring
paper clips, such as Hunt No. 4 or equivalent, are suitable. Naturally,
this simpler system involves manually clamping and unclamping
the sheet.
FIGURE 2
Sheet-Hanging Device (Air-Operated Release)
Trolley
Since Plexiglas® acrylic sheet is opaque to most wavelengths
in the infrared spectrum, the surface exposed to the heater
absorbs almost all the energy. The rest of the sheet is heated
largely by conduction.
Since Plexiglas® acrylic sheet is an excellent insulator, the surface
exposed to the heater may overheat before the rest of the sheet
is hot enough for forming. This phenomenon is relatively common
in thicker sheet. The rate of radiant heat input can be decreased
but that would result in a longer heating cycle. Consequently, for
optimum production efficiency, double-sided infrared heaters
should be used for sheet 0.118 inches or greater in thickness.
Single-sided infrared heaters are not recommended for sheet
thicker than 0.177 inches.
Infrared heating time is critical and must be closely controlled
because of the high surface temperatures (usually 600°F to 1500°F)
of the heaters and the large amount of energy they emit. Infrared
heaters are usually controlled by a timing switch on a relay circuit,
varying the on-off cycle to meet the requirements of particular
forming operations. Fifteen-second cycle timers are recommended;
a thermocouple and a controller may be used as well. Varying
the distance between the heaters and the sheet regulates the
rate of heat input effectively. This distance should be a minimum
of two to three times the element spacing to eliminate hot spots.
Track
Hunt No. 4
Paper Clip
6
Infrared radiant heating is not recommended for heating large
areas where the most uniform heating is necessary in order to
obtain excellent optical properties in the formed part. With infrared
heaters, power required is approximately 10 watts per square
inch of sheet area.
FIGURE 3
Sheet Hanging Device (Air-Operated Release)
Sheet Metal
Clamp Guide
Spring
Assembly View
of Hanging Device
18
"
Center Line
of Trolley
Note:
Clamp Opener Located on
Track Outside Oven Near
Press or Forming Equipment
Air to Cylinders
8'—
0"
18
"
Clamps and Hanger
Assembly Roll on Track In
and Out of Oven
3-way FootOperated Air
Valve
Schrader
Co. Model 1255
1
2 ⁄2" Minimum
Travel
Spring Specs: -3lb. Pull
When Stretched to 9"1
Approx. ⁄4" O.D.
1
1" x ⁄2" Cold
Rolled Steel Bar
Stock Length to
Suit Cylinder and
Travel
Return Spring
1
2" x 1 ⁄2" Angle x
Trolley Hanger
and Track
Richards Wilcox
Co. or Equal
1⁄
4"
Drill Out Clamp Rivet
to Accommodate
Dia. Rod
1⁄
4"
2" Channel
Spring Clamp
Hargrave Co. Size
No. 2 or Equal
(shown in closed
position)
90 psi Air In
Air Cylinder
Schrader Co.
Push Type No.
1796 D or Saval
Co. Model A-26
Airplane Type
1⁄
4"
View AA
2"
Section Through Hanger
3⁄
4"
Split Pipe—Knurled—
Braze to Spring Clamp
Dia. Rod
6"
1⁄
4"
Pipe Spacer
1⁄
4"
Pipe Spacer
(1 for every 4 clamps)
7
The strip heater should have supports on both sides to hold
the Plexiglas® acrylic sheet. See Figure 4. The supports should
be parallel to and above the heater so the heater does not
touch the surface of the sheet. The supports should be shielded
from direct radiation to minimize the temperature. This is especially
true for Plexiglas® MC acrylic sheet, which could develop mark-off
if too hot. Direct contact with the hot element will destroy or
severely distort the surface of Plexiglas ® acrylic sheet.
1
Therefore, the material should be kept at least ⁄8 inch from the
tube. To form a bend with a large arc, a wider band of Plexiglas®
acrylic sheet is heated by holding the sheet at a greater distance
from the heater or by using a wide strip heater.
FIGURE 4
Typical Strip Heater
Plexiglas®
Acrylic Sheet
Sheet Metal
Heater Housing
Insulated Resistance Coil
Strip Heating
Strip heaters are used to heat Plexiglas® acrylic sheet to forming
temperature along a straight line so it can be bent along that line.
A strip heater is usually electric with the element made from a
nichrome wire resistance coil. The wire should be insulated with
china clay tubing or porcelain beads and can also be encased in
a copper, Monel®, or Pyrex® tube. Flexible fiberglass-nichrome
wire tape strip heaters are available for heating both curved surfaces
and flat surfaces.
To form material more than 0.236 inches thick and for fast
production, two heaters should be arranged to heat both
surfaces simultaneously.
Plexiglas® MC acrylic sheet can be readily strip heated and
bent. Heating cycles will be slightly shorter than those used with
Plexiglas® G cell cast acrylic sheet and the material must be
closely monitored to prevent overheating (greater than 410°F
surface temperature), which can result in surface bubbles.
Adhering to the following guidelines will help to ensure satisfac­
tory bends with no bubbling:
■ Use a heater that develops an element surface temperature
of approximately 800°F (not glowing red), and a sheet support
surface temperature of less than 225°F (water cooled if necessary).
1
Maintain a uniform sheet to element spacing of ⁄4 inch.
■ Heat 3mm (0.118 inches) material from one side for approximately two and a half minutes.
■ Preferably, heat 4.5mm (0.177 inches) material from both
Selectively heating a narrow area of plastic to forming
temperature without heating the adjacent material induces a
considerable amount of stress into the bend area upon cooling.
This could lead to premature failure by cracking or crazing. Avoid
exposing the bend area to materials such as cleaners, solvents,
polishes or waxes; although normally safe, these products could
craze the surface of the sheet. Warpage can occur in the sheet
in very long bends with short legs because of stress relaxation.
The only way to ensure against either of these conditions is to
heat the entire sheet and cool the bent formed part evenly.
The heater should be equipped with a thermoregulator to
prevent overheating the Plexiglas® acrylic sheet.
8
sides simultaneously. When using a single element heater,
flip the sheet every minute for about three minutes.
■ Material that is 6mm (0.236 inches) thick should be heated
from both sides simultaneously or flipped every minute for
about four minutes.
While strip heaters employing hotter elements than 800°F
can be used for bending Plexiglas® MC acrylic sheet, the risk of
bubbling increases as the element temperature increases. For
example, if the sheet is heated 15 seconds too long with a glowing
red element (about 1500°F), bubbling is very likely.
GRAPH 1
30-Second Modulus Curves
4000
Modulus of Elasticity in Tension, psi
(Measured 30 Seconds After Application of Load)
3000
2000
1000
900
800
700
600
500
400
Plexiglas® G Cell Cast Acrylic Sheet
300
200
100
90
80
70
60
50
40
Plexiglas® MC Acrylic Sheet
30
20
220
230
240
250
260
270
280
290
300
310
320
330
340
350
360
370
380
Temperature, °F
Other Methods of Heating
Hot water or atmospheric pressure steam will not heat
acrylic sheet to high enough temperatures for forming.
Hot oil can be used, but it makes the sheet difficult to handle
and necessitates subsequent cleaning. A light mineral oil such
as transformer oil is preferred. The oil must be kept clean and
must be washed off after forming.
Microwave sources do not heat Plexiglas® acrylic sheet efficiently.
Special Considerations for Forming
Plexiglas MC Sheet
As the 30-second modulus curves in Graph 1 show, the forming
characteristics of Plexiglas® MC acrylic sheet and Plexiglas® G
cell cast acrylic sheet differ in certain respects when heated to
the same given forming temperature.
Plexiglas® MC acrylic sheet, when heated to a given forming
temperature, is somewhat softer than similarly heated cell cast
acrylic sheet. Therefore, more clamps should be used with
Plexiglas® MC acrylic sheet, and large sheets should be hung in
the oven from the long edge to provide maximum support. If
heated at too high a temperature or allowed to remain in the
oven longer than necessary, the Plexiglas® MC acrylic sheet
will tend to “flow,” becoming elongated and narrow, and may
9
pull out or tear from the supporting clamps. Plexiglas® MC
acrylic sheet will also tend to adhere to hot metal clamps. To help
prevent problems, preclamp the sheet in a tenter frame before
heating.
Heated Plexiglas® MC acrylic sheets will tend to stick together
more readily than cast sheets that touch one another in the
oven or that are accidentally folded during forming.
Fabricators can avoid thermal damage to Plexiglas® MC
acrylic sheet by controlling temperature and heating time
cycles to avoid bubbling.
Plexiglas® MC acrylic sheet may require pre-drying overnight
at 180°F, if it has been exposed to conditions of high relative
humidity for extended periods of time. This situation usually
applies only to sheet that will be formed at the upper end of
the forming temperature range (greater than 325°F) when
extremely sharp detail is desired.
When Plexiglas® MC acrylic sheet is heated without a tenter
frame, it will shrink approximately 2 percent in the direction of
manufacture. Whereas Plexiglas® G cell cast acrylic sheet, when
heated uniformly to forming temperatures, will shrink about 2
percent in length and width, and will increase in thickness by
about 4 percent.
10
The forming temperature range of Plexiglas® MC acrylic sheet
is 275°F to 350°F. The recommended forming temperature is
325°F. At this temperature, the material has good extensibility
and will vacuum thermoform to detail that is adequate for most
applications. Forced forming methods such as plug and ring
and free blowing are best performed at this temperature also.
The higher forming temperatures should be used only when
maximum vacuum detail is needed.
Heating cycle times for Plexiglas® MC acrylic sheet in a circulatingair oven are the same as for Plexiglas® G cell cast acrylic sheet—
one minute for each 10 mils (0.010 inches) of material thickness.
For example, the approximate heating time in a circulating-air
oven set at 325°F for 3 mm (0.118 inches) thick Plexiglas® MC
acrylic sheet is 12 minutes. The heating cycles for acrylic sheet
heated by infrared heaters are considerably less than for heating
in a circulating-air oven.
Parts formed from the sheet should be cooled to approximately
140°F before being removed from the mold. Cooling time and
total cycle time depend on the sheet thickness, part configuration,
mold temperature and forming technique used. Overall cycle
times for Plexiglas® MC acrylic sheet are similar to cycle times
for other thermoformable sheet materials.
FORMING TEMPERATURES & CYCLES
Forming temperature for Plexiglas® acrylic sheet must be carefully
controlled within the forming range (see 30-Second Modulus
Curves—Graph 1).
Excessively high temperatures may cause degradation of the
sheet. Excessively low temperatures may cause excessive stresses
leading to crazing in service. The optimum temperature at which
Plexiglas® acrylic sheet should be formed will vary according to the
method of forming and the ultimate shape desired (Table 1). In
specific applications the optimum forming cycle should be
determined by trial.
Plexiglas® acrylic sheet should be heated to temperatures
from 290°F to 350°F. These are sheet temperatures. The formability
of hot Plexiglas® G acrylic sheet changes little within these
temperature ranges. However, the formability of Plexiglas® MC
acrylic sheet changes greatly. Higher temperatures may reduce the
tear resistance of the sheet and may also impair its physical
properties without visible change in appearance and before
bubbling occurs on the surface.
Further, if the Plexiglas® acrylic sheet is too hot, the surface
will be softer and more likely to pick up fingerprints, glove marks,
specks of dirt and imperfections (called mark-off) from the form.
These marks may require extensive polishing to remove. Mark-off
can be removed from Plexiglas® G acrylic sheet by reheating.
Thinner material must be heated to higher temperatures than those
used for thick stock because the thin material cools more rapidly.
In some cases, the sheet may be heated above the required
minimum forming temperatures, removed from the oven, and
the surfaces allowed to cool slightly before they come in contact
with the mold. In this procedure, the center of the sheet remains
hot enough that excessive stress is avoided, but the surfaces
are sufficiently cool to minimize mark-off.
Note: Never use a narrowly focused air blast, as this process
can chill small areas of the heated sheet, thus creating stress
and warpage. Large fans are sometimes employed for cooling,
but care must be exercised to ensure that cooling is uniform
and even.
The temperatures recommended in Table 1 are intended as a
guide in establishing proper forming conditions. Variations for
the different methods are based on average time requirements
for handling the Plexiglas® acrylic sheet between the oven and
the forming apparatus and for clamping the sheet and completing
the forming operation.
Sufficient but not excessive time should be allowed for the
sheet to be heated throughout to forming temperature. This
time will depend on oven temperature, air velocity in the oven
and the sheet thickness. In general, at least one minute heating
time should be allowed for each one hundredth inch of thickness
of the Plexiglas® acrylic sheet, when both surfaces are exposed
to the circulating hot air, e.g., a sheet 0.236 inches thick should
be heated for approximately 24 minutes. Times can be adjusted
as experience dictates.
Rather than control the oven temperature for each different
thickness of sheet, it is general practice to control the oven at
the highest temperature required for any Plexiglas® acrylic sheet
being heated, then control the temperature of the sheet by the
length of time it is kept in the oven.
Excessive exposure times at forming temperatures should be
avoided as this can cause edge degradation and/or surface
degradation (bubbling or yellowing, or both) of the sheet. For
example, with Plexiglas® G acrylic sheet, bubbling can occur at
350°F after five hours, and at 400°F after only about 15 minutes.
Recommended Sheet Temperatures*
for Forming Plexiglas® Acrylic Sheet
Plexiglas® Acrylic Sheet
Regardless of Sheet Thickness
Type of Forming
Two-Dimensional (Drape)
Air Pressure Differential
Without Form (Free Blown)
G
290°-310°F
350°F
MC
275°-290°F
325°F
Stretch (Dry Mold Cover)
Air Pressure Differential
With Male Form (Snapback)
320°F
340°F
310°F
325°F
Air Pressure Differential
With Female Form
350°F
325°F
Stretch with Male Form (Plug & Ring)
350°F
325°F
TA B L E 1
*Caution: Do not heat Plexiglas G sheet above 360°F or for more than one hour.
Plexiglas® MC acrylic sheet should be heated to required forming temperature and then
formed. Do not heat more than the required time.
11
Time Available for Forming
Slow Cooling
Heated Plexiglas® acrylic sheets must be completely formed
before their surface and internal temperatures drop below
275°F. Unless forming is completed at or above this temperature,
the parts will be cold formed with resultant inherent stresses
within the material.
After the Plexiglas® acrylic sheet has been formed, it should be
allowed to cool slowly and uniformly. Slow, uniform cooling
will help minimize internal stress and often results in truer
contours, particularly in thick parts. Many fabricators cover a
formed part with a soft, heavy blanket for these reasons.
These stresses cannot be removed by annealing unless the
annealing takes place at temperatures high enough to cause
significant deformation of the part.
The parts should be cooled to a temperature of 150°F to 170°F
for Plexiglas® G acrylic sheet and 10 degrees lower for Plexiglas®
MC acrylic sheet before removing it from the form. Otherwise,
the material will tend to go back to its flat sheet shape. On the
other hand, formed parts should not remain on the form till
completely cooled or cracking may occur. Definite heating,
forming, and cooling time cycles should be established for
production of uniform parts.
The time available for forming heated Plexiglas® acrylic sheet
before it cools below the minimum forming temperatures (Table 2)
depends on the sheet thickness and temperature, air temperature in
the fabricating shop and mold material and temperature. To
minimize the time required to form the heated sheet, place the
forming apparatus near the heating oven and use conveyors,
quick-acting clamps and other time-saving devices.
If it is not possible to form the sheet within the time limits given
in Table 2, it may be necessary to enclose the forming apparatus
and maintain the area within the enclosure at a higher ambient
temperature. Ambient temperatures to 120°F may double or
triple the time available for forming.
Another method of increasing the time available for forming
is to keep the forming molds warm. This can be done by using
a properly spaced bank of infrared lamps focused on the molds
or by using metal molds that are cored for circulating warm
water or oil. Metal molds cool the Plexiglas® acrylic sheet faster
than those made of wood, plaster or the thermosetting resins;
hence, it is more important that they be kept warm during
forming. The mold should not be allowed to get too hot or the
sheet will require longer cooling times. Best results are usually
obtained with a mold temperature of about 150°F to 170°F for
Plexiglas® G acrylic sheet, and 10 degrees lower for Plexiglas®
MC acrylic sheet.
Reforming
Properly formed acrylic parts will retain their shape if kept below
180°F for Plexiglas® G acrylic sheet and 10 degrees lower for
Plexiglas® MC acrylic sheet. If exposed to higher temperatures,
they tend to revert to the original flat sheet form. This property,
called elastic memory, prevents forming acrylic parts in several
stages as in sheet metal pressing, but permits the fabricator to
reheat and reform the sheet if he makes an error in forming.
When reforming, the sheet should be heated for flattening and
reforming at the same time to keep at a minimum the total
time the sheet is exposed to oven temperature (see Caution
noted under Table 1).
Maximum Time Available for Forming
Plexiglas® Acrylic Sheet*
Plexiglas® Acrylic
Plexiglas® Acrylic
Sheet Thickness (in)
Sheet Temperature
.060
360°F
.060
320°F
.060
285°F
.118
360°F
.118
320°F
.118
285°F
.236
360°F
.236
320°F
.236
285°F
.472
360°F
.472
320°F
.472
TA B L E 2
12
285°F
Maximum Available Forming
Time (Minutes)
75˚F
120˚F
0.5
0.4
0.1
0.8
0.5
0.1
1.5
0.6
0.1
2.5
1.3
0.2
1.3
1.0
0.3
1.5
1.0
0.3
4.0
1.5
0.3
6.5
2.0
0.5
*In still air before it cools below minimum forming temperature, 275°F
for Plexiglas® G and Plexiglas® MC acrylic sheet.
FORMING EQUIPMENT
Presses
Clamping Rings and Clamps
The amount of pressure needed to form Plexiglas® acrylic
sheet is much less than that needed to form metal. Presses
with a capacity of one ton per square foot of platen area are
adequate for forming, including corrugating.
Some means should be used for holding the edges of the sheet
against the form during forming and cooling. For very simple shapes,
rubber bands can be fastened to the form and snapped over the
edges of the formed Plexiglas® acrylic sheet. For more complicated
shapes, a clamping ring is made to fit the contours of the form. The
clamping ring is brought to bear on the edges of the sheet to hold
it in place. The ring should be hinged or located by guide pins on
the form so that it will always be in correct position in relation to
the form, allowance being made for the thickness of the sheet. The
ring may also be used as a template of the finished part so that
when the plastic is cool, the “trim line” may be scribed while the
part is on the form. The Plexiglas® acrylic sheet should not be scribed
until it has cooled since the material contracts during cooling.
The following rule of thumb can be used to calculate the total
force in pounds required to form the average sign face by the
plug and ring method: Calculate the perimeter of the basic shape
and all interior shapes in inches and multiply the total by 30.
Vertical presses may have (a) a fixed lower platen and a moving
upper platen or (b) moving lower and upper platens. Horizontal
presses in which the platens move on a horizontal plane are
also available. Such presses may be operated by air or hydraulic
cylinders that have a stroke of at least 18 inches. (The stroke should
be three times the maximum depth of draw.) Platens should have
a steady rate of travel of from 5 to 15 feet per minute without
1
chatter. They should be rigid and not deflect more than ⁄8 inch
when loaded to capacity.
Figure 5 shows several different types of clamps and clamping
rings that can be used to hold the Plexiglas® acrylic sheet during
forming. The surface of the clamping ring that contacts the hot
Plexiglas® acrylic sheet should provide a nonslip grip. The clamp
faces can be surfaced with a variety of materials such as coarse
FIGURE 5
Types of Clamps and Rings for Forming
Drawing and Clamping
Force Exerted by Press
Hot Plexiglas® Acrylic Sheet
Supported by Male Mold
Plexiglas® Acrylic
Sheet
Clamp Ring
Plexiglas® Acrylic Sheet
˝C˝ Clamp
Plexiglas®
Acrylic Sheet
Forming with
Air Pressure
Observation
Window
Forming with
Vacuum
Spring-Loaded Flange
Vacuum Line
Toggle Clamp
Toggle Clamp
1⁄
2"
Leg—at Each
Clamp
Toggle Clamp
Clamp Ring
Plexiglas®
Acrylic Sheet
Continuous
Angle
Plexiglas® Acrylic
Sheet
Masonite
Die Stock
Toggle Clamp
3⁄
4"
Pipe
Plexiglas®
Acrylic Sheet
Wide Band
Saw Blade
32 Teeth—
Tack Weld
to Bar
Plexiglas®
Acrylic Sheet
Steel Bar
1⁄
2" x 1"
Masonite
Die Stock
13
sandpaper, ping pong paddle rubber or perforated metal. The
choice of clamping method will usually depend on the number
of parts and rate at which the parts must be formed. If only a
few parts are to be formed, wood clamps or “C” clamps may be
used. For high production rates, toggle clamps or air cylinder
actuated clamping rings are used. Forming presses and clamping
fixtures may be combined in many different ways to meet the
need for versatile forming equipment or specialized devices
capable of high production rates. Forming equipment may be
constructed from readily available parts and materials to suit any
requirement. A few typical designs are discussed below.
Double-action presses that use air or hydraulic clamping and
forming cylinders are illustrated in Figure 6. Cylinders are
conveniently mounted on a frame constructed of steel I-beams.
The forming cylinder, fitted with the mold, may move up or down;
if the motion is down, a removable support should be provided
for the heated Plexiglas® acrylic sheet to prevent the sheet from
draping into the cavity before the mold descends. If the forming
cylinder moves up, the mold supplies support for the heated
sheet.
Double - Action Presses
Press Ram
(closed)
Press Ram
(open)
Heated
Plexiglas®
Acrylic Sheet
®
Formed Plexiglas
Acrylic Sheet
Compressed
Spring
Clamp Ring
Male Mold (stationary)
Spring
Support
Spacers
Bolt
Overtravel
Lower Platen
Typical spring to allow up to 6" depth of formed part
1
1 ⁄2" pitch dia., .093 dia. spring wire
22 working coils, both ends flattened & ground
12" free height
Springs spaced 6" center to center around edges
Spacers
Press Ram (open)
Spring
Supports
Clamp
Spring
Adjusting
Bolt
Upper Clamp Ring
Heated Plexiglas® Acrylic Sheet
Clamping Cylinder
Plexiglas®
Acrylic
Sheet
Spring-Loaded Clamp for Forming
Plexiglas® Acrylic Sheet
Male
Mold
(moves)
FIGURE 6
Press Frame
FIGURE 7
Clamping Ring
(pressure head or
vacuum box may
be substituted)
Lower
Clamp Ring
Support
(stationary)
Part Section
Showing Mold
Closed
Mold
Forming Cylinder
Forming Cylinder
Clamping
Cylinder
Press Frame
Mold
Removable
Support for Plexiglas®
Acrylic Sheet
14
Plexiglas®
Acrylic
Sheet
Precompress all springs 3" with adjusting bolts to produce approximately
10 lbs./running inch initial clamping force. Clamping pressure increases
as male mold closes to form the Plexiglas® acrylic sheet. Press must have
enough total force to form the part plus compress the clamping
springs.
A number of cylinders may be required to develop the clamping
pressure required to hold the Plexiglas® acrylic sheet without
slippage. Alternatively, individual clamping cylinders may be
replaced with a clamping ring. Double-action presses can also
be adapted to forming by air pressure differential by replacing
the clamping ring with a ruggedly constructed vacuum or
pressure box.
FIGURE 8
Adjustable Frame and Vacuum/Pressure Table
Separate clamping cylinders are not essential. Another widely
used design shown in Figure 7 makes use of spring-loaded
clamping rings that are actuated by the single press ram. The
male mold may be stationary, providing a support for the heated
Plexiglas® acrylic sheet, or it may be driven into the sheet by
the ram. The surfaces of the clamping ring should be serrated
to prevent slippage of the sheet. The press must have enough
total force to compress the clamping springs as well as form
the sheet. The springs should develop a clamping force of
approximately 10 pounds per running inch.
The sketches in Figure 7 show spring-loaded clamps on a
vertical press but they can also be used to good advantage
with a horizontal press.
An especially versatile and inexpensive forming fixture for
vacuum or pressure forming is shown in Figure 8. The device
consists of an adjustable clamping frame constructed of wood,
Masonite die stock and iron pipe mounted on a press over a
vacuum/pressure table which serves as the lower platen.
15
The construction of the vacuum/pressure table is illustrated
by the sketch, Figure 9. A perforated plywood face (pegboard) is
sealed to a box frame, supported by spacer blocks. A vacuum
outlet is attached to the side of the frame and a compressed air
line is brought through the plenium to the underside of the
perforated board.
FIGURE 9
Vacuum/Pressure Table
PSB - 50
Page 4
An important feature of the design of this forming fixture is the
ease with which the size of the clamp can be adjusted to form
parts ranging from about 12 x 12 inches to several feet in length
and width. The front side of the frame is stationary, the left side
can slide forward, the right side moves to the left and the back
can move in both directions, so that the clamp can be set to form
any size square or rectangle within the outer dimensions of the
press. In Figure 8, the clamp is shown extended to full size; in
Figure 10, the sketch shows the clamp set to form a small square.
The illustration, Figure 8, shows the forming fixture installed on
a self-leveling press; if a conventional press such as that in Figure
10 is used, a supporting pipe should be installed in the right rear
corner, as shown, to keep the load in balance when small parts
are formed. The supporting pipes are threaded with right- and
left-hand threads on opposite ends so that the clamp may be
leveled simply by turning the pipes.
FIGURE 10
Adjust to a Small Size Part
To form parts such as skylight domes with compressed air, the
vacuum/pressure table is first covered with kraft paper to block
off the vacuum holes, then covered with light flannel to diffuse
the air and prevent chilling of the heated sheet when it is clamped
in the press. A dome of any desired height within the daylight
opening is formed by admitting compressed air as shown in
Figure 11. The front side of the clamping frame is hinged at top
so it may be raised to facilitate removing the part after forming.
FIGURE 11
Vacuum forming is carried out in a similar manner using a
perforated mold on the vacuum/pressure table. Vacuum holes
outside the area of the piece to be formed are covered with kraft
paper. Heated Plexiglas® acrylic sheet is clamped to the mold, and a
vacuum is drawn, forming the sheet.
Free Blow Forming
The convenient design of this adjustable forming fixture may
be adapted to any specialized forming operation. For example,
if it is to be used only for forming shallow parts, the daylight
opening may be much smaller than in the model illustrated.
Figure 11
16
Vacuum Forming Equipment
The equipment required for vacuum forming consists of a
source of vacuum, an accumulator tank, piping, valves and fittings,
and the vacuum pot or chamber in which the actual forming is
done (Figure 12).
The vacuum chamber is generally made of steel plate, all seams
being welded and airtight. The chamber should have a flange
around the edge for attaching clamping rings and should be as
small as the part will permit to minimize the amount of air, that
must be removed during forming. The completed part should
be at least 2 inches from the inside of the vacuum pot to prevent
touching and to prevent uneven heat transfer from the hot sheet
to the cool tank wall.
If only a few pieces are to be made, the chamber can be built
of heavy plywood or Masonite® die stock on a frame of wood
two-by-fours. The joints are sealed by a caulking compound applied
to all edges before assembling. Any gun or knifing compound can
be used and will maintain the seam, even though there is a certain
amount of movement of the joints as the pressure within the pot
is reduced. Such movement often cracks a glued joint and causes
leakage. For additional sealing, masking tape can be applied to
the outside of all seams and Spraylat® or a similar material may
be brushed on the outside.
Clamping rings can be made of plywood, rigid phenolic laminate
or Masonite die stock, with a center hole cut to the desired
shape. Interchangeable clamping rings will permit production of
a variety of parts on a single vacuum chamber. Metal rings should
not be used unless they are temperature controlled, because they
chill the Plexiglas® acrylic sheet too rapidly. Plywood may be used
in some cases if mark-off in the flange area is not objectionable.
Hardwood plywoods give better results than softwood plywoods.
When the detachable rings are used, a tubular gasket or “O” ring
can be applied between the metal flange and the removable ring.
The greater the pressure on such a gasket, the tighter the seal.
In practice, the hot Plexiglas® acrylic sheet is clamped between
the detachable ring and a hold-down ring, by any of the various
means suggested. This second ring may be knurled or scored to
prevent the sheet from slipping. Often the edge of the detachable
ring is beaded to make an airtight seal. Such a seal is important
not only for preserving the vacuum, but also to avoid drawing in cool
air, which may chill the sheet unequally. A small leak can make
the difference between the production of good and bad parts.
A vacuum pump, driven by an electric motor that will handle
25 to 50 cubic feet of air per minute at 27 inches of mercury, is
satisfactory for forming all but the largest parts. Steam, water,
air venturi or ejector valves can also be used. Whatever source
is used, it should maintain at least 22 inches of mercury at the
rated volume to make the system most useful.
FIGURE 12
Equipment for Vacuum Forming
Vacuum
Gauge
Vacuum
Release
Valve
Accumulator Tank
Vacuum
Pump
Drain
Tenter
Frame
Vacuum
Chamber
Plexiglas® Acrylic
Sheet
Form
17
The vacuum system should include an accumulator tank to
prevent fluctuations in air pressure during forming. Galvanized
steel domestic hot water tanks, or any tank able to withstand
external pressures of 15 psi, are recommended in capacities of
30 to 100 gallons. The larger sizes give extra capacity at little
extra cost and permit greater flexibility in the system. The vacuum
pump should be capable of pumping a volume of air per minute
(at minimum of 22 inches of mercury) approximately twice the
volume of the system, including the accumulator tank and the
vacuum pot. The accumulator tank should be fitted with a drain.
FIGURE 13
Typical Vacuum System with Automatic Control
Solenoid Valve
Controlled by
Phototube
Vacuum
Tank
Plexiglas® Acrylic
Sheet
Hold-Down
Ring
Vacuum
Gauge
Vacuum
Pump
Standard steel piping and valves of one inch diameter or larger
are normally used. At least one section of the piping between
accumulator and forming chamber should be made of flexible
metal reinforced hose so that the chamber can be moved or
the connection changed easily. Short, large-diameter pipes and
valves reduce losses and make a more efficient system.
Vacuum
Release
Valve
Observation
Windows
Vacuum Pot
A pipe from the vacuum chamber is connected with a standard
pipe tee. One side of the tee is connected through a valve to the
vacuum line; the other, through to a second valve, is open to the
atmosphere. The pressure, and hence the rate and depth of draw,
can be accurately controlled by adjusting the two valves.
This control may be manual or automatic (Figure 13). In one
mechanical system, the Plexiglas® acrylic sheet, as it is being
formed, touches a micro-switch which activates a solenoid. This
solenoid operates an air line controller, which in turn, controls the
modulating valve on the vacuum line. In another system, the
sheet, as it is being drawn, interrupts a beam of light focused on a
photoelectric cell. The change in current in the cell operates a
solenoid valve, through relays to open and close the vent line
on the vacuum pot. A high-lift or needle-valve is adjusted on
the vacuum line so that the volume of air being drawn from the
vacuum pot is balanced by the volume of vented air. In this way
the correct rate of draw and depth is maintained.
18
Plexiglas®
Acrylic Sheet
Light Source
Phototube
FORMS FOR PLEXIGLAS®
ACRYLIC SHEET
Contour Tolerances and Effects of Forming
1
Contour tolerances of plus or minus ⁄8 inch can be maintained
in many forming operations, but for free-blown sections, particularly
1
in large sizes, tolerances of up to plus or minus ⁄2 inch may have
to be allowed. The reduction in thickness caused by deep drawing
will tend to lighten the color or translucency of colored Plexiglas®
acrylic sheet, so that the color of the drawn pieces may not match
the original color of the flat sheet, especially where the part is
viewed with transmitted light. This graduation of color can be
used to advantage in such applications as lighting fixture shields.
Wood Forms
The best woods for forms are kiln-dried hardwoods such as
birch or cherry. Well-dried soft woods, such as white pine, poplar
or Philippine mahogany, may also be used if sound and free of
knots. All woods must be sealed to prevent changes in shape
and dimensions, which occur with atmospheric changes. Synthetic
resins, high-temperature varnish or casein should be used because
shellac or regular varnish will soften at forming temperatures.
Wooden forms should be made so that side grain of the wood
is on the surface throughout, since end grain may produce
distortions in the finished pieces.
Shrinkage Allowances
Resin Impregnate Forms
When the final dimensions of the formed parts are critical,
forms must be built sufficiently oversize to allow for shrinkage
when the parts cool from forming temperature to room temperature.
3
A shrinkage allowance of approximately ⁄32 inches per foot should
be made in designing female forms for Plexiglas® acrylic sheet
1
and about ⁄16 inch per foot for male forms. Remember it is
better to remove too little material from a form than too much.
Also, surfaces of the forms should extend beyond the trim line.
This permits the use of slightly oversize sheet, which simplifies
handling and compensates for the slight tendency of the plastic
to curl away from the form and flare at the edges.
Masonite die stock, a compressed, lignin-bonded material,
cloth or paper-base phenolics and Impreg or Compreg, special
resin-impregnated woods, can also be used for forms for Plexiglas®
acrylic sheet. These materials can be built up, laminated, and
finished to produce excellent molds with polished, grainless
surfaces which will resist wear and will not be affected by normal
moisture changes.
Materials for Forms
Since most drape forms for Plexiglas® acrylic sheet are not
subjected to great pressure, they may be constructed of wood,
plywood, sheet metal or sheet laminates bent over wooden or
metal formers. Except for long production runs, forms need not be
made of metal or materials generally used for sheet metal forming.
Either convex or concave forms can be used, but usually the
convex or male shape is preferred (Figure 16). Forms for compound
three-dimensional or deep-drawn shapes are more difficult to
make, but are made the same way as patterns for castings.
Molds for thermoforming Plexiglas® MC acrylic sheet may be
constructed of most common mold materials. Plexiglas® MC
acrylic sheet will reproduce the mold detail extremely well,
however, so it will also reproduce any mark or defect on the
mold surface. For applications in which surface quality is important,
the mold surface must be well finished. Tooling plastic resin and
cast metal alloys make the best thermoforming molds.
19
Metal Forms
FIGURE 14
Forms can be made of cast metal or fabricated from plate and
bar stock. Some low-melting alloys can be cast to good finish
for small forms. These alloys are especially convenient for model
work. Aluminum, bronze, brass, and high-melting alloy molds can
be cast by regular foundry techniques. They should be carefully
finished because pits, blowholes, and other surface defects will
be reproduced in the formed acrylic parts. Provision should be
made to control the temperature of metal forms, since metal lends
itself well to coring/heat transfer (unlike most other mold materials).
Gypsum Form
3⁄
16"
3" Thick
Plaster
Cast
Cast Forms
Casts of various materials can be made from the original
wooden form. Allowances for the shrinkage of the casting as well
as for the contraction of the Plexiglas® acrylic sheet must be
made when building the original. If the final form will require
finishing to obtain the smooth surface necessary for forming
Plexiglas® acrylic sheet, allowance must also be made for the
material to be removed during finishing.
Gypsum Forms
Satisfactory forms can be cast from high-strength gypsum
products. Specific instructions for their use are supplied by the
manufacturers and should be followed exactly.
No finishing is needed if a good smooth surface is applied to
the original pattern and the casts are properly made. Gypsum
forms should be made with a hollow shell from 2 to 4 inches
thick, not solid (Figure 14). They should be reinforced with steel
rods and wire-mesh welded into a shape to take any tension or
bending stresses. Use steel strips around the edges and at
clamping points to strengthen and stiffen the form and prolong
its life.
20
Deformed Reinforcing
Bars and Expanded
Metal Lath
Steel Plate
Resin Forms
Grease-Covered Forms
Very good forms can be cast from phenolics and other
thermosetting resins. The dimensions of phenolic molds should
be checked from time to time.
Felt mold covers saturated with grease can be used to minimize
mark-off and eliminate objectionable optical distortion. It is not
recommended to try to form Plexiglas® MC acrylic sheet in this
manner. To prepare a grease form, cover the mold with a felt
blanket, heat the covered mold and work grease into the felt
until it is thoroughly saturated.
The form should be cast from a carefully finished female mold,
according to directions supplied by the manufacturer. Polyester
and epoxy glass reinforced lay-ups can be used for either male
or female molds. A smooth gel coat on the surface against which
the Plexiglas® acrylic sheet is to be formed will help reduce
mark-off. Resin forms may be more expensive than gypsum
forms, but provide a smoother, tougher surface when properly
made from the correct materials.
Surfaces of Forms
The surfaces of forms should be free of waves and other
variations in contour that might cause optical distortions in
the finished part. Surfaces of drape or snapback forms are usually
covered with soft cotton flannel cloth, flannelette, velvet, or billiard
felt. The nap of these cloths helps prevent mark-off which might
otherwise result from small dirt particles or irregularities in the
surface of the mold. For covering three-dimension forms use suede
rubber or flocked rubber sheeting which can be stretched to the
contour of the form.
In use, the mold must be kept hot almost to the point where
the grease runs. The temperature of the Plexiglas® acrylic sheet
should be higher than when using uncovered forms. The best
parts are produced when the form is heated to 170°F for Plexiglas®
G acrylic sheet, and the surface of the grease is heated to
approximately the sheet temperature. It is usually necessary to
apply a fresh layer of grease after forming each part because
much of it is removed by the Plexiglas® acrylic sheet. The form
should be mounted below the sheet to avoid dripping grease
on the material while the sheet is being clamped in place.
After forming, wash the grease from the formed parts with
kerosene, hexane or aliphatic naphtha. Do not use chlorinated
or aromatic hydrocarbons, lacquer thinners or other solvents
that are harmful to Plexiglas® acrylic sheet.
A water-emulsifiable grease may be used. This may be washed
off with water.
While the fabricator is generally interested in minimizing mark-off,
very attractive designs can be intentionally embossed in the plastic
surface during forming of decorative parts. Coarsely woven cloths,
wire meshes, patterned metals, and the other materials applied
to the surface of the form can impart pleasing texture to the
Plexiglas® acrylic sheet and enhance the appearance of a
formed part.
Forms used for translucent Plexiglas® acrylic sheet should
contact only the inside surface since mark-off does not show
on the outside. Where female portions of molds are required to
obtain the desired shape, they should be relieved so only the
perimeter contacts the hot sheet. An important exception is
translucent lighting fixture pans and shields. The exterior surface
of the pans can be made nonspecular by forming against a
sandblasted aluminum mold or similar form. (See Surface
Embossing on page 33.) Prepainted Plexiglas® acrylic sheet
should be formed so that the non-painted surface contacts the
mold whenever possible.
21
FORMING METHODS
Preparation of Sheets for Forming
Hot Plexiglas® acrylic sheet can be handled much like a sheet
of pure gum rubber and approximately the same force is required
to stretch it. For making simple shapes, especially when thick
sheet is used, the weight of the material is often sufficient and
only if considerable stretching is required should much pressure
be applied. Most three-dimensional shapes may require the use
of vacuum, air pressure, or mechanically or hydraulically actuated
forms or combinations of these. Forms should be kept clean and
brushed off before each piece is formed. They should also be
stored carefully when not in use to protect them from denting,
chipping, or warping. Such defects will show up in the Plexiglas®
acrylic sheet on forming.
Before heating the Plexiglas® acrylic sheet, cut somewhat
oversize, remove the masking paper. Any specks of adhesive
that adhere to the sheet can be removed by dabbing with the
gummed side of the masking paper. If the sheets are dusty or
dirty, they should be washed with soap and water and rinsed well.
The sheet should be dried thoroughly by blotting with soft cotton
cloth. Otherwise, solids dissolved in ordinary tap water will bake
into the plastic surface when the material is heated. Operators
should wear soft cotton gloves to avoid fingerprinting or
scratching the sheets and should grip it only in the clamping area.
sheet requires a minimum radius of 300 times the thickness.
Table 3 lists the minimum permissible radius of curvature
versus Plexiglas® acrylic sheet thickness.
Cold forming Plexiglas® acrylic sheet beyond these limits may
result in crazing of the material because of stresses beyond
those recommended for a continuous load.
Strip Heat Bending
The simplest method of forming Plexiglas® acrylic sheet along a
straight line is to use a strip heater, which heats the sheet to
forming temperature so that it can be formed along that line. The
method lends itself to the rapid production of simple boxes,
picture frames and similar items, but is generally limited to
straight line bends. The process is usually used for small parts
where the length of the bend is relatively short. Long bends
(over 24 inches) tend to bow.
The Plexiglas® acrylic sheet, unmasked along the bend line, is
placed over the heating element and allowed to remain until it
softens. (See Figure 4.) Excessive heating times should be avoided
as the sheet could bubble and degrade.
FIGURE 15
Two-Dimensional Forming
V-Groove Cut Before Heating and Bending
Cold Forming
t
Machined
Groove 90˚
t
Plexiglas® acrylic sheet can be bent while cold to simple
shapes by springing the material into a curved frame. The radius
of the curvature should be a minimum of 180 times the thickness
of the sheet for Plexiglas® G acrylic sheet. Plexiglas® MC acrylic
Depth of
Cut—3⁄4
Sheet
Thickness
Cold-Forming Minimum Radius of Curvature
Thickness
(in)
Minimum Permissible Radius of
Curvature (in)
G
MC
0.060
10.8
0.080
14.4
17.6
21.2
31.9
42.5
63.7
85.0
0.098
0.118
0.177
0.236
0.354
0.472
TA B L E 3
22
N/A=Not Applicable.
N/A
N/A
29.4
35.4
53.1
70.8
106.7
N/A
After Strip Heating
Groove Can Be Sealed
by Capillary Cementing
After heating, the Plexiglas® acrylic sheet should be bent to the
required shape quickly and held, usually in a fixture, until cool. In
production, a number of strip heaters and fixtures can be
arranged so as to make several folds in one operation.
FIGURE 16
Male Drape Form
Continuous Clamp
Sharper, straighter bends can be made by strip heating if a
90° groove for right-angle bends is machined along the bend
line on what will be the inside of the formed part before heating
(Figure 15).
Strip heating and bending any thermoplastic induces a high
degree of stress into the material, which can result in cracking
or crazing. The degree of stress depends upon the length of the
bend, width of the heated area, material thickness and the amount
of material on either side of the bend. Heating as narrow an area
as possible, consistent with good design practice, will minimize
overall stress in the part but concentrate it, thereby increasing
the crazing possibility. An effective manner in reducing the stress
level is to machine a V-notch about halfway through the thickness
of the material. The groove is positioned on the inside of the
bend, which develops a sharp radius not in accordance with
good structural design practice of 2-3 times the material thickness.
However, aesthetics (crisp corners and no crazing) often outweigh
structural considerations in non-critical applications. No cement
should be applied to the V-notch after bending.
Drape Forming
Drape forming is used for two-dimensional shapes and for
mild three-dimensional shapes.
Plexiglas®
Acrylic
Sheet
Three-Dimensional Forming
Three-dimensional shapes in Plexiglas® acrylic sheet are formed
by stretching the heated material to the required contour. The
force required to stretch the sheet can be supplied by manual
labor, mechanical pressure, hydraulic pressure, vacuum, air
pressure, or combinations of these, depending on the forming
method being used.
After heating to the proper temperature (Table 1), the Plexiglas®
acrylic sheet should be removed from the oven and carefully
draped over the form (Figure 16). The edges of the sheet will tend
to curl away from the form and should be held against the form
by a clamping ring or rubber bands until the part is cool. Most
uniform cooling and best contour tolerances can be obtained if
the parts are covered with a soft blanket or flocked rubber sheet
and allowed to cool slowly. This is most important when close
contour tolerances and good optical properties are required in
a thick acrylic part.
It is best to use a female drape form, as the part will lay into
the mold by the weight of the sheet. This reduces mark-off.
23
Free Forming
Free forming is used to form three-dimension shapes entirely
by the use of air pressure differentials—vacuum or positive
pressures without the use of male or female forms (Figures 17
and 18). Parts produced by this method usually have excellent
optical properties.
In free forming, the heated sheet is simply clamped over a
vacuum pot or pressure head and drawn or blown to shape. There
is no possibility of mark-off since the sheet does not contact any
form. Further, when an air pressure differential does the work of
forming, the manpower required is reduced, and cooling is relatively
uniform because both surfaces of the Plexiglas ® acrylic sheet
are exposed to air.
When the opening in the vacuum pot or pressure head is
circular, the finished part approximates a section of a sphere for
shallow-drawn parts. Since the center of the sheet stretches most,
this area thins out first and therefore cools first. The thicker areas
around the sides and the circumference continue to stretch since
they are still hot. Thus deep draws produce a bulging or fish bowl
shape. See Figure 19 for ratio of thickness at the apex to original
sheet thickness of blown spherical parts of different depths.
Even if the opening of the vacuum pot is square or triangular,
the Plexiglas® acrylic sheet tends toward a spherical shape, since a
sphere has the smallest surface area of any shape for any given
volume. An analogy is the blowing of soap films through different
shaped openings. The resultant blown or drawn shapes are often
called “free form” or “natural” shapes.
FIGURE 17
Free Forming with Vacuum
FIGURE 19
Apex Thickness – Free Formed Spherical Parts
Clamp
t
D
t
Plexiglas®
Acrylic
Sheet
Free Forming with Air Pressure
Clamp
Plexiglas®
Acrylic
Sheet
Masonite Die Stock
Solenoid Valve
Controlled by
Phototube
Baffle
Air Supply
Ratio of Apex Thickness to Original Sheet Thickness
FIGURE 18
t
Vacuum
Clamping
Ring
% D (Height)
Solenoid Valve
Controlled by
Phototube
Light Source
for
Phototube
t
Phototube
Unit
Clamping Ring
1.0
.9
Apex Thickness
.8
.7
.6
.5
.4
.3
.2
.1
0.0
0.1
0.2
0.3
0.4
Ratio of Height to Base Diameter
24
0.5
A variety of shapes can be formed by differential air pressure
by altering the shape of the pot opening in the third dimension
(Figure 20). This can materially reduce thinning out of the sheet,
depending on the shape of the part.
The choice between the use of vacuum and positive pressure
in forming will usually depend upon the equipment at hand. In
general, vacuum forming is preferred because it is safer, easier
to control, and simpler to seal. It is important that the joints in
the vacuum pot be sealed against air leaks, which could cause
uneven cooling of the part. Sometimes the maximum pressure
differential possible with vacuum (14.5 psi maximum) is not enough
and positive pressures must be used. Original tooling costs may
be lower for positive air pressure forming, as only a pressure
head, clamps, and clamping ring are required.
FIGURE 20
Some Free Form Shapes Obtainable with Various Openings
Three-Dimensional Openings
25
Estimating Pressure Required for Free Blowing
or Vacuum Forming
Figure 21 is an alignment chart useful in estimating the pressure
required to form various diameters of hemispheres from various
thicknesses of Plexiglas® acrylic sheet.
Example:
Problem: Estimate the pressure required to form a 25-inch
inside diameter hemisphere from 0.236-inch thick Plexiglas® G
acrylic sheet.
Solution: Draw a straight line through the 25-inch diameter
on Scale A and 0.236-inch thickness on Scale B. Continue this
straight line to intersect Scale C. Read off estimated pressure at
the point of intersection of the line and Scale C – 4.8 psi required.
The alignment chart can also be used to estimate the force
required for other methods of forming, other degrees of draw,
and other than spherical shapes by estimating the diameter
corresponding most closely to the desired curvature or by
bracketing the least and most favorable geometry of the
required part.
Vacuum Snapback Forming
Vacuum snapback forming is often used when the desired
part varies from a true surface tension shape. This method is
based on the tendency of hot, formed acrylic to return to its
original flat sheet form. Plexiglas® MC acrylic sheet has limited
snapback capabilities.
Like vacuum forming, snapback forming is done in a vacuum
pot (Figure 22). After the heated sheet is drawn into the pot to a
larger bubble than the male mold, a male form – which reproduces
the inside contour of the desired part – is lowered and locked
inside the bubble formed by the Plexiglas® acrylic sheet. Since
the sheet is still hot, it has a tendency to resume its flat sheet form.
Therefore, as the vacuum is gradually released, the sheet snaps
back slowly against the form.
In vacuum snapback forming, all stretching is done by pressure
differentials. Less mark-off is produced by this method than by
mechanical stretch forming because the Plexiglas® acrylic sheet
is stretched before it comes in contact with the form instead of
being stretched as it is drawn across the form.
26
In snapback forming, the Plexiglas® acrylic sheet will not snap
back into reverse curves and will not follow rapid changes of
contour very accurately. Nevertheless, it is possible to obtain
1
contour tolerances of plus or minus ⁄8 inch or closer in snapback
1
forming compared with plus or minus ⁄4 inch to plus or minus
1⁄
2 inch for free forming.
An integral flange is formed where the part has been clamped
3
to the vacuum pot. This flange is usually at least ⁄4 inches wide
and provides a strong and simple mounting. The contour of the
flange can be held to fairly close tolerances, regardless of the
tolerances maintained on the rest of the part.
The form should be constructed with a draft of at least three
degrees to permit easy removal of the formed part. Small vents
should be provided in the male form to permit escape of air that
may be trapped between the form and the sheet. Reverse curves
can be produced by connecting the vacuum line to vents in
depressed areas on the forms.
Vacuum Drawing or Blowing into a Form
This method is also based on air-pressure differentials. The
heated Plexiglas® acrylic sheet is clamped directly to the edges
of a female form, and the sheet is either drawn down by vacuum
or forced down by air pressure into the form.
When the shape closely resembles a “free form” shape, parts
formed by this method will have fairly good optical properties.
Every part of the sheet comes in contact with the form at
approximately the same time, and the pressure can be controlled
so that mark-off is held to a minimum.
When the shape is not a “free form” shape, one area of the
sheet comes in contact with the form before the other areas
are fully drawn, and the pressure at the areas in contact with
the form will be great enough to cause surface defects.
If good optical properties are most important, the form can be
greased as in "grease forming." This type of forming is not
recommended for Plexiglas® MC acrylic sheet. It is very difficult to
attach a felt, greased blanket to the inside of a female mold, and
none is ordinarily required. Special polybutene greases, which do
not change their viscosity radically with changes in temperature,
should be used. The mold should be warmed with electric
elements, infrared lamps, steam, or oil to approximately 170°F,
FIGURE 21
Sub-Atmospheric or “Vacuum-Forming” Range
t
Super-Atmospheric or “Pressure-Forming” Range
t
t t
Alignment Chart for Estimating Pressure Required to Form Hemispheres from PLEXIGLAS® Cell Cast Acrylic Sheet
70
80
10
0
90
70
80
10
0
90
60
50
45
40
35
30
25
20
15
10
9
8
7
6
5
4
3
2
1
Scale C—Approximate Required “Free-Forming” Pressure Differential—Pounds Per Square Inch
Scale B—Thickness of Plexiglas® Cell Cast Acrylic Sheet—Inches
1.75
.708
.354
.220
.118
2.00
1.50
.944
.472
.236
.177
.098
Alignment Chart for Estimating Pressure
Required to Form Hemispheres from Plexiglas Cell Cast Acrylic Sheet
60
50
45
40
35
30
25
20
15
10
9
8
7
6
5
4
3
2
1
Scale A — Inside Diameter of Hemisphere—Inches
FIGURE 22
1
and then coated with a film of grease approximately ⁄16
inch thick. The grease film must be reasonably uniform. It
should be smoothed and fresh grease added as needed. The
surface of the grease should be heated to as near the forming
temperature as possible with infrared lamps just before the
heated sheet is clamped in place for forming.
Vacuum Snapback Forming
Air Cylinder
Vent Hole
Male Mold
Clamp Ring
Clamp
Masonite
Die
Stock
Gauge
Window
Vacuum
Plexiglas® Acrylic Sheet
After Snapback
Plexiglas®
Acrylic Sheet
Forms used for vacuum drawing or blowing into a form should
be well made of sturdy materials and adequately reinforced.
The mold should have a uniform thickness in the forming area
to ensure equal deflection under forming pressure or vacuum
and constant heat transfer rates. When the mold is greased,
positive air pressure is preferred, for vacuum tends to draw
entrapped air from the pores of the mold, causing bubbles in
the grease layer and distortions in the formed acrylic part. When
the mold is not greased, either positive pressure or vacuum
may be used. Pressure or vacuum molds should have outlets at
the points of deepest draw and should provide a tight seal
between flange and Plexiglas® acrylic sheet to avoid air leaks.
27
Vacuum drawing or blowing into a form is used often for forming
parts that differ quite radically from free form shapes, but in
which mark-off is not objectionable. In fact, the method can be
used to reproduce in Plexiglas® acrylic sheet the mirror image
of any pattern or device in the female mold. Very fine detail can
be picked up in this way, depending on the amount of pressure
used. Close approximations of geometric shapes can also be
produced. Corners, of course, will tend to be round, the radius
of curvature depending on the pressure used. Sharp corners will
tend to thin out because of the greater depth of draw in the
corners. Heavy clamping pressure is required when high positive
air pressure differentials are used.
To calculate the clamping pressure required to prevent leaks,
multiply the pressure required to form the part by the projected
area of the part at the clamping ring.
Example:
50 psi required to form
Area: 50 x 60 inches = 3000 sq in
Clamping pressure:
50 x 3000 = 150,000 pounds
Manual Stretch Forming
Manual stretch forming is often used when the compound
curvature is not great, when optical distortion is not objectionable,
and the number of parts to be made does not warrant setting
up mechanical equipment. The sheet is heated to forming
temperature and clamps are fastened to the edges, six to ten
inches apart (Figure 23).
Holding the Plexiglas® acrylic sheet with these clamps, the
forming crew draws the sheet down over the form. For some
shapes, one edge of the sheet may be clamped to the form,
and the sheet stretched over the form from the other edge. The
sheet should be stretched as uniformly as possible. Use slow,
steady tension and let the sheet stretch gradually.
After the sheet has been stretched, a clamping ring can be
clamped in position around the edges, leaving the crew free to
work on other forms.
28
FIGURE 23
Manual Stretch Forming
Compound
Curved
Male Drape
Mold
Yoke
Formed
Plexiglas®
Acrylic
Sheet
Slip Forming
Vacuum Assist Plug and Ring Forming
Plexiglas® acrylic sheet is usually clamped around the edges
after heating before it is formed. This puts the whole sheet in
tension and it stretches more uniformly and wrinkles are not
apt to form. In some cases, in order to obtain a thicker finished
part, a predetermined amount of Plexiglas® acrylic sheet is
allowed to slip under the clamping ring to reduce thinning out of
the sheet.
Deeply drawn parts (ratio of width of opening to depth of part
is one or less) with little thickness can be made if vacuum is used
to assist the draw. The ring support is made into an airtight box
to which the heated Plexiglas® acrylic sheet is clamped. Vacuum
is applied to draw the sheet to about half the desired depth. The
plug is then forced into the drawn sheet to secure the desired
shape. When the plug is “home,” air is vented into the box to
allow the Plexiglas® acrylic sheet to shrink onto the plug. This
method produces a more uniform final part thickness than by
the method above or by vacuum snapback.
Wrinkles tend to form outside the ring around the edge of the
piece, limiting the amount of material that can be allowed to slip
in. When sufficient material has slipped in, the rings are clamped
more tightly and the draw is completed. Hot or insulated clamping
rings may be used to avoid chilling the material.
FIGURE 24
Plug and Ring Forming
Plug and Ring Forming
A modification of stretch forming known as the plug-and-ring
method, operates on a principle similar to the familiar embroidery
hoop (Figure 24).
The hot Plexiglas® acrylic sheet is clamped over a ring and
the center of the suspended material is pushed in with a tapered
plug. The ring is made larger than the outside of the male form or
plug, with allowance, of course, for the thickness of the sheet.
Plug-and-ring forming usually has the disadvantage of producing
excessive mark-off, particularly at the inside corners of the formed
part where mark-off is most difficult to remove. This disadvantage
is not important for parts where optical properties are not important,
nor for forming translucent sheets. Avoid forms with flat surfaces
and minimal draft for Plexiglas® MC acrylic sheet because they
tend to develop chill lines on the formed part.
Air Cylinder
Clamp Ring
Clamp
Plexiglas®
Acrylic
Sheet
29
Blowback Forming
FIGURE 26
One of the main advantages of blowback forming is in the
reproduction of complex drawn shapes. Also, deeply drawn parts
made by the blowback forming method show less reduction in sheet
thickness than when vacuum assist plug and ring forming is
used. This method consists of clamping a heated Plexiglas® acrylic
sheet between a pressure box and an oversize clamping ring
(Figure 25). A male form shaped to the inside contour of the
part is then pressed into the sheet to the required depth and
locked in this position, thus stretching the sheet. Compressed
air at 50 to 100 psi is then admitted to the pressure box, forcing
the heated sheet back against the male form. The parts are held
in this position by air pressure until the sheet cools and becomes
rigid. The forming cycle must be fast enough to ensure that the
Plexiglas® acrylic sheet is still well above the minimum forming
temperature as it is blown back against the male form.
Using Dummy Block to Prevent Webbing
Care must be used in design to prevent the Plexiglas® acrylic
sheet from webbing at the corners when it is blown back against
the male mold. One way to overcome this tendency is to add
dummy blocks to the mold to equalize stretching in all directions.
Figure 26 shows a formed letter “C” made with and without
dummy blocks. The heavy lines indicate corner fold produced in
the formed letter made without dummy blocks. The two blocks
included in cutaway portions of the other mold completely
overcome this tendency.
FIGURE 25
Blowback Forming
Air Pressure
Plexiglas®
Acrylic
Sheet —
Stretched
by Male Mold
Plexiglas® Acrylic
Sheet —
Blown Back
Vent
Male Mold
30
Billow Forming
FIGURE 27
The main advantage of billow forming (Figure 27) is good control
of wall thickness.
Billow Forming
This method consists of clamping to a pressure box a heated
blank that is larger than the projected area of the part. The box
must be strong and airtight. A bubble is blown in the sheet
clamped to the box by admitting air to the box. The male mold
is then forced down into the bubble. Contact with the mold tends
to prevent further thinning due to friction and cooling. As the
male mold descends the bubble will wrap around it because of
the air pressure maintained in the box. The pressure should be
relief-valved so that excess pressures are not built up as the male
mold and formed Plexiglas® acrylic sheet displace the volume.
The male mold must be vented at undercuts or any areas that
trap air between the mold and the formed part. The vented air
can also be used to blow the formed part off the mold.
Press Ram
Vacuum Connection
or Vent
Male Plug
Billowed Plexiglas®
Acrylic Sheet Bubble
Clamping
Frame
3
Ring ⁄4"
Masonite
Die Stock
Final Position
Baffle
Steel
Pressure Box
Female
Ridge
31
Ridge Forming
FIGURE 28
Ridge forms are open or skeletal rather than solid forms and they
may be used to good advantage in many forming operations. They
are generally easier and less costly to construct than solid forms.
Ridge Forming
Ridge forms may be used with nearly all methods of forming
including press forming, vacuum or pressure forming, snapback
or reverse blow forming and vacuum platen forming. Ridge forms
contact the heated Plexiglas® acrylic sheet only along ridges
necessary to determine the size and shape of the formed part.
Consequently, mark-off is minimized.
Corrugating Plexiglas® Acrylic Sheet
(ridge forming)
Staggered
Metal "T's"
Plexiglas®
Acrylic
Sheet
Because hot Plexiglas® acrylic sheet tends to resume its original
flat shape, the areas between ridges and clamping ring are
stretched taut. Areas on a plane enclosed by ridges tend to form
flat planes in the formed part. In other shapes with ridges that
do not fall on the plane, the intervening areas tend to be concave.
One of the simplest ridge forms is that shown in Figure 28 for
corrugating Plexiglas® acrylic sheet by press forming. The form
consists of rows of parallel metal T-bars mounted in alternating
positions on upper and lower platens.
Ridge forms combined with vacuum platens provide a simple
means of forming an unlimited variety of parts with a minimum
outlay for materials and equipment. Simple ridge forms are made
from plywood and stock metal shapes, which are then used to
vacuum form decorative Plexiglas® acrylic sheet panels.
Clamp for Edge of Sheet
FIGURE 29
Ridge Forming Using Air Pressure and Vacuum
Male Die
Force
Vent
Contour
Controlled
by Air
Pressure
The principles of ridge forming can be extended to the
construction of both male and female forms (Figure 29) so that
reverse curves, flanges and flutes can be formed with a minimum
of distortion.
Vent
Vacuum
Several shapes can be formed in a single piece by dividing a
vacuum box with partitions and using separate control valves
for each compartment. The Plexiglas® acrylic sheet itself forms a
seal when it is drawn against the ridges or partitions. The pressure
differentials that may be used are limited by the tension in the
sheet as it is stretched across the opening. A tighter seal can
be made if ridges in the male form press the Plexiglas® acrylic
sheet against corresponding grooves or ridges in the female
form.
32
Female Die
Air Pressure Valve
Contour
Controlled
by Vacuum
Male and Female Forming
FIGURE 30
®
Male and female forming may be used to form Plexiglas
acrylic sheet by surface molding and embossing the material
between matched male and female dies. Both surfaces of the
Plexiglas® acrylic sheet formed by this method are in continuous
contact with the forms and will reproduce the mold surfaces if
high enough pressures are used.
Matched male and female dies usually cost more than tooling
used for other forming methods. These dies should be metal to
withstand the high pressures that may be developed. If used
hot, metal dies will prolong cooling. They should, therefore, be
cored to permit heating and cooling.
Surface Embossing
Air Supply (50-75 psi)
Plexiglas® Acrylic
Sheet
Surface Embossing
Embossing is often used to produce a patterned surface finish
on Plexiglas® acrylic sheet parts for applications such as lighting
fixture panels where spectacular reflections might be annoying.
The patterned surface is obtained by blowing the hot sheet
against a mold having a textured surface finish (Figure 30).
Water or Steam
Coils for Heating
Mold
White Wool Felt
or Patterned Surface
Positive air pressures of 50 to 75 psi (4 to 6 tons total force per
square foot) must be used to obtain a uniform overall pattern
on cast sheet. Much lower positive pressure or vacuum pressure
will produce similar results with Plexiglas® MC acrylic sheet. Large
high-capacity presses are required to provide enough clamping
force to resist these pressures. The press must also close quickly so
that the surface of the sheet does not cool too much before forming.
Metal mold surfaces must be kept hot and temperatures must
be uniform over the mold surface to prevent chilling of the sheet
and loss of surface detail. If a matte finish is desired, the
surface of the mold should be covered with pure white wool
felt, which will act as an insulating blanket and reduce the chilling
effect of the mold while producing a uniform matte surface of
the Plexiglas® acrylic sheet.
33
GENERAL HEALTH & SAFETY
PRECAUTIONS
Care must be taken whenever thermoforming any thermoplastic
including Plexiglas® acrylic sheet. The heat of thermoforming
Plexiglas® acrylic sheet may result in the release of vapors or
gases, including methyl methacrylate (MMA) monomer. However,
thermoforming Plexiglas® acrylic sheet in accordance with
recommended techniques at recommended temperatures and
with adequate ventilation should not result in harmful concentrations
of vapors or gases in the workplace. High concentrations of
MMA vapors can cause eye and respiratory irritation, headache
and nausea. The OSHA Air Contaminant Standard for MMA
places the maximum permissible exposure level at a time
weighted average (TWA) of 100 ppm. Altuglas International
recommends a TWA for MMA of 50 ppm.
It is always good practice to provide local exhaust ventilation
as close to the point of possible generation of vapors as practical.
Suggestions for the design of exhaust ventilation systems are
provided in Industrial Ventilation — A Manual of Recommended
Practice, published by the American Conference of Governmental
Industrial Hygenists (2004), and American National Standards
Institute Fundamentals Governing the Design and Operation of
Local Exhaust Systems, ANSI/AHAZ9.2-2001.
Before attempting to make forms or conduct grease forming
with materials suggested in this manual, the user should become
familiar with the properties of these materials and the precautions
necessary for their safe usage. Material Safety Data Sheets
should be available from the manufacturer for these purposes.
Plexiglas® acrylic sheet is a combustible thermoplastic material.
The same fire precautions observed with the handling and use
of any ordinary combustible material should be observed when
handling, storing, or using Plexiglas® acrylic sheet.
34
Altuglas International Sales Offices
For more information, call your local Altuglas International
sales office or Altuglas International headquarters.
Americas Headquarters
Altuglas International
Arkema Inc.
2000 Market Street
Philadelphia, PA 19103-3222
USA
Tel.:
800-523-1532
215-419-7000
Fax:
215-419-5511
Detroit Office
Altuglas International
Arkema Inc.
1050 S. Milford Road
Suite 102
Highland, MI 48357
USA
Tel.:
248-887-2245
Fax:
248-887-0452
Chicago Office
Altuglas International
Arkema Inc.
2300 N. Barrington Road
Suite 432
Hoffman Estates, IL 60195
USA
Tel.:
847-490-8455
Fax:
847-884-0353
Mexico Office
Arkema SA de CV
Río San Javier 10
Viveros del Rio, Tlalnepantla
54060 Edo. de Mexico
Mexico
Tel.:
52-555-366-4166
Fax:
52-555-362-0699
Brasil Office
Arkema Química Ltda.
Av. Ibirapuera
2033 Sao Paulo – SP 04029-901
Brasil
Tel.:
55-11-5056-8579
Fax:
55-11-5051-4780
The statements, technical information and recommendations contained herein are believed to be
accurate as of the date hereof. Since the conditions and methods of use of the product and of
the information referred to herein are beyond our control, Arkema expressly disclaims any and all
liability as to any results obtained or arising from any use of the product or reliance on such
information; NO WARRANTY OF FITNESS FOR ANY PARTICULAR PURPOSE, WARRANTY OF
MERCHANTABILITY OR ANY OTHER WARRANTY, EXPRESS OR IMPLIED, IS MADE CONCERNING THE
GOODS DESCRIBED OR THE INFORMATION PROVIDED HEREIN. The information provided herein
relates only to the specific product designated and may not be applicable when such product is
used in combination with other materials or in any process. The user should thoroughly test any
application before commercialization. Nothing contained herein constitutes a license to practice
under any patent and it should not be construed as an inducement to infringe any patent and the
user is advised to take appropriate steps to be sure that any proposed use of the product will not
result in patent infringement.
See MSDS for Health & Safety Considerations.
Altuglas® and Plexiglas® are registered trademarks of Arkema.
All other trademarks listed are the property of their owners.
©2006 Arkema Inc. All rights reserved.